RU2506465C1 - Siphon - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to automatic hydraulic devices. A siphon includes suction and drain elbows and a siphon start-up mechanism. A suction tube of the suction elbow is equipped with an air cap and a shell, and the siphon start-up mechanism is made of the above parts of the suction elbow and the drain tube of the drain elbow. Lower edge of the air cap is installed below upper edge of the shell, but above the lower edge of the suction tube, and the lower edge of the drain tube of the drain elbow is installed below lower edge of the air cap, but above the lower edge of the suction tube. Air cap volume is larger than that of the shell, and flow passage of the section tube of the suction elbow is smaller than a slot-type flow passage of the shell, but larger than flow passage of the drain tube of the drain elbow.

EFFECT: invention allows simplifying a siphon structure, improving operation reliability and enlarging the range of change of the supplied flow.

9 dwg

Description

The invention relates to hydraulic devices and can be used in many sectors of the national economy for the automatic conversion of a continuous liquid flow with a small flow rate into a discrete flow with a high flow rate. More specifically, this invention can find application for a dosed supply of liquid in the food and chemical industries, in irrigation systems and in various water washing devices.

Known siphon, which is part of the device for irrigation, and consisting of a suction and drain elbows, the last of which is connected to the collector of the supply tube with a tap and the charging mechanism of the siphon, consisting of an ejector of the mentioned collector and the tube of the liquid level sensor in the storage tank with suction and drain parts. The siphon also contains a breather tube. The ends of the sensor tube passing through the hole in the wall of the storage tank and the breather tube are inserted into the nests in the collector cover, while the ejector of the siphon charging mechanism is made in the form of a tube with holes in its wall [RF Patent No. 2175831, cl. A01G 25/00 (Siphon - positions 4 and 13 in Figure 1, Figure 2 and Figure 3)].

The disadvantage of this siphon is the design complexity and low reliability. In this siphon design, the function of the ejector is performed by one of the irrigation pipelines with water outlets, which leads to unstable operation of the siphon as a whole due to possible clogging of water outlets. The speed of the siphon start-up depends on the performance of the ejector, which is difficult to ensure at low input costs. The siphon does not have a vacuum breakdown mechanism, as a result of which its operability is ensured in a narrow range of input flow rate changes, which sharply reduces its applicability in various sectors of the national economy.

The closest technical solution (prototype) is a siphon containing suction and drain bends, the last of which is connected to the collector, a supply pipe with a tap and a siphon charging mechanism, consisting of an ejector, the mentioned collector and a tube of a liquid level sensor with suction and drain parts, this feeding tube is made with the main and additional outputs, and the liquid level sensor tube is equipped with a chamber located under the main output of the feeding tube, divided by a partition on the upper and lower the cavity communicating between a channel to form a lower air chamber of the water trap furthermore the suction pipe portion of liquid level sensor located in the upper part of the chamber, and the drain part has an opening above the suction part [RF patent №2306460, Cl. F04F 10/00 (prototype)].

The disadvantages of this siphon are the design complexity and low reliability. The principle of operation of the ejector does not allow a quick (instant) start-up of the siphon, which worsens the flow parameters of the siphon drain. Efficiency in a narrow range of changes in the input flow sharply reduces its applicability in various sectors of the economy. When mounting this siphon, the suction elbow and the chamber are installed in the storage tank, which leads to the need for refinement (window cutting) of the tank cover and, therefore, to the complication of manufacture.

The aim of the proposed invention is to simplify the design of the siphon, increase reliability in operation and increase the range of variation of the input flow rate.

This goal is achieved by the fact that in the siphon containing the suction and drain knee and the siphon trigger mechanism, the suction pipe suction pipe is equipped with an air cap and a cup and the siphon trigger mechanism is made of the mentioned parts of the suction knee and the drain knee drain pipe, while the lower edge of the air cap installed below the upper edge of the cup, but above the lower edge of the suction tube, and the lower edge of the drain pipe of the drain elbow is installed below the lower edge of the air cap, but above the lower th suction tube edge. The volume of the air cap is made larger than the volume of the cup, and the bore of the suction tube of the suction elbow is made smaller than the slotted bore of the cup, but larger than the bore of the drain tube of the drain bend.

The essence of the alleged invention is shown in the figures, where Fig. 1 is a General view of the siphon, Fig. 2 is a structural diagram of a siphon, Fig. 3 is a diagram of an installation of a siphon and a supply tube to a storage tank, Fig. 4 is a view A in Fig. 3, Fig. .5 - Siphon charging circuit, FIG. 6 - Status of the siphon after charging, FIG. 7 - Status of the siphon before commissioning, FIG. 8 - Status of the siphon after commissioning (liquid is drained from the storage tank) and FIG. 9 - The condition of the siphon after the end of its operation (drainage of liquid from the storage tank stops).

Siphon 1 (Figure 1) contains suction 2 and drain 3 knees. The suction elbow has an outlet fitting 4 and a suction pipe 5 equipped with an air cap 6 and a glass 7 with stiffeners 8 and a stop 9, and the drain elbow 3 consists of a coupling 10 and a drain pipe 11 (Figure 2). The glass 7 by means of stiffening ribs 8 and the stop 9 is rigidly fixed to the suction tube 5. The siphon elements are located relative to each other as follows: the lower edge of the air cap 6 is installed below the upper edge of the glass 7, but above the lower edge of the suction pipe 5, and the lower edge of the drain pipe 11, the drain elbow 3 is installed below the lower edge of the air cap 6, but above the lower edge of the suction tube 5, in addition, the volume of the air cap 6 is larger than the volume of the cup 7, and the passage section of the suction tube 5 is satisfied less slit passage section of the glass, but most of the flow section 11 of the tube drain drain the knee 3.

For the operation of the siphon 1, it is necessary to install it in the tank 12 with the lid 13 and the hole 14, fix the supply tube 15 to the side wall of the tank by means of a valve 16 with a control flag 17 and charge the siphon 1.

Install the siphon 1 in the tank 12 as follows: Unscrew the drain elbow 3 from the suction elbow 2, place the suction elbow 2 in the reservoir 12 and, having directed the glass 7 vertically downwards, insert the outlet nozzle 4 into the hole 14. Screw the drain elbow 3 onto the outlet nozzle 4 by the coupling 10 to the end, and guide the end of the drain pipe 11 vertically downward (Figure 3 and Figure 4).

Charge the siphon 1 as follows: Turn the drain pipe 11 of the drain elbow 3 vertically upwards, avoiding the deviation of the glass 7 from the vertical position. Pour the working fluid from the glass into the drain elbow 3 until it appears in the tank 12 (Figure 5). After the appearance of the working fluid in the tank 12 (siphon charging is completed), turn the outlet of the drain pipe 11 clockwise by turning it vertically downward, avoiding the deviation of the glass 7 from the vertical position. Charging the siphon 1 is the filling of the glass 7 with the working fluid to its upper edge (Fig.6). Close container 12 with cover 13. Siphon 1 is ready for operation.

Siphon 1 operates as follows. The working fluid with a small flow rate q, set by the valve 16 and the control flag 17, through the supply tube 15 enters the accumulation tank 12 and slowly accumulates in it to the level of the lower edge of the air cap 6 (lower level of the OHC), without making any impact on the condition of the siphon 1 Next, the accumulation of liquid in the tank above the NU begins (the beginning of the “accumulation" cycle). The liquid level in the storage tank 12 rises slowly. The liquid level also rises in the cavity of the air cap 6, but with a large lag behind the level in the tank 12, since the air in the cap 6 and the water column in the glass 7 impede its increase. During the period of increasing the liquid level in the tank 12 under the action of a column of water in the tank air is compressed in the cap 6 and slowly squeezes the liquid out of the cup 7 with ribs 8 and the stop 9 into the atmosphere through the exhaust pipe 5, the outlet nozzle 4, the coupling 10 and the drain pipe 11. In this case, the liquid level in the cap approaches the upper edge of the cup 6, a ur the liquid level in the glass drops and approaches the lower edge of the drain tube 5. The equilibrium of compressed air in the cap against the glass 7 is supported, on the one hand, by the accumulated liquid column in the container 12, located above the lower edge of the air cap 6, and on the other hand, by the liquid column in the suction tube 5 (Fig.7). Upon reaching the liquid level in the tank 12 of the upper level (WU), due to the fact that the volume of the air cap is made larger than the volume of the cup, and the passage section of the suction tube 5 is made smaller than the slotted passage section of the cup 7, but larger than the passage section of the drain tube 11, the level the liquid in the cap 6 still remains below the level of the upper edge of the cup 7, and compressed air, breaking the lower edge of the suction tube 5, enters it and reduces the density of the liquid in it. Further, the ingress of air into the cavity of the suction tube 5 and the process of reducing the density of the liquid in it takes on an increasing character. The equilibrium of compressed air in the cap and the cup is sharply violated, and the liquid under the pressure of the column in the tank 12, squeezing the air out of the air cap and the cup into the atmosphere, is drained from the tank 12 with the cover 13 into the atmosphere to the consumer with a large flow rate Q that exceeds the input flow q many times through the air cap 6, the slit section between the cup 7 and the outer diameter of the suction pipe 5, the suction pipe 5, the outlet fitting 4 and the drain pipe 11 (the beginning of the “drain” cycle) (Fig. 8).

The liquid level in the tank 12 begins to decline, and when the lower level (NU) is reached, which corresponds to a level slightly lower than the lower edge of the air cap 6, air enters the cavity of the air cap 6 and the vacuum siphon 1 breaks off abruptly. The lower level drops below the lower level the edges of the air cap 6 and provides a sharp breakdown of the siphon vacuum due to the fact that the diameter of the air cap is much larger than the diameter of the drain tube 11. At the same time, part of the working fluid from the cavity of the air drain cap is returned to the container 12, and the part continues to merge into the atmosphere through the drain pipe 11. After the vacuum has been removed and the cavity of the air cap communicates with the atmosphere, the siphon 1 continues to work until the water level in the glass 7 drops to the level of the lower edge of the drain pipe 11. When the liquid level in the glass reaches the level of the lower edge of the drain pipe 11, the drain from the siphon stops (end of the “accumulation - drain” cycle). The liquid columns are balanced in the suction pipe 5 and the drain pipe 11, the glass 7 remains filled with water to the level of the lower edge of the drain pipe 11. Then the liquid begins to slowly drain from the drain pipe 11 into the atmosphere, and from the suction pipe 5 to the glass 7, raising the liquid level in a glass 7 and flooding the lower end of the suction tube 5 (automatic charging of the siphon), thereby preparing the siphon for the next “accumulation-drain” cycle (Fig. 9).

Further, the working cycles of slow accumulation of liquid in the storage tank 12 with the input flow q and its quick discharge with the flow Q are automatically repeated.

Thus, by supplying the siphon suction tube with an air cap and a cup, and performing a siphon start mechanism from the above-mentioned parts of the suction knee and the drain knee drain pipe, and observing that the lower edge of the air cap is installed below the upper edge of the cup, but above the lower edge of the suction tube , and the lower edge of the drain pipe of the drain elbow is installed below the lower edge of the air cap, but above the lower edge of the suction pipe, simplified design of the siphon and increased its reliability s work. The diameter of the air cap is significantly larger than the diameter of the drain pipe 11 has allowed to increase the range of variation of the input flow q. Compared with the prototype, tubes and small-diameter holes are excluded from the design of the siphon and its trigger mechanism, which virtually eliminates the possibility of clogging of the working channels.

In the workshops of the Federal State Budgetary Scientific Institution Research Institute "Rainbow" in 2012, experimental samples of the proposed siphon were made in the amount of 6 pcs. Tests of two samples in laboratory conditions and four samples in greenhouses of personal plots showed high reliability, ease of use and performance in a wide range of input flow rates . The maximum input flow rate of these siphons exceeded the maximum required flow rate for irrigation of the greenhouse by 8 times. The samples, having worked a total of more than 21,000 hours with an accumulation-discharge cycle of 3 hours and 40 minutes, did not commit a single failure. In this case, the time for the siphon to be fully started was up to 0.5 sec, and the time for discharging the siphon after emptying the tank 12 was up to 1 sec.

The application of the proposed invention in the national economy will increase the reliability and efficiency of hydraulic systems, where it is necessary to automatically convert a continuous flow of liquid with a low flow rate into a discrete flow with a high flow rate.

Claims (3)

1. Siphon containing a suction and drain knee and a siphon trigger mechanism, characterized in that the suction pipe suction pipe is provided with an air cap and a cup, and the siphon trigger mechanism is made of the mentioned parts of the suction knee and drain knee drain pipe, while the lower edge of the air cap installed below the upper edge of the glass, but above the lower edge of the suction tube, and the lower edge of the drain pipe of the drain elbow is installed below the lower edge of the air cap, but I suck it above the lower edge shch tube. 2. The siphon according to claim 1, characterized in that the volume of the air cap is made larger than the volume of the glass. 3. The siphon according to claim 1, characterized in that the flow area of the suction pipe suction pipe is smaller than the slotted passage of the glass, but larger than the flow area of the drain pipe of the drain elbow.

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